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Meet the
Scientists!
The Investi-gator • http://www.scienceinvestigator.org 39
How Glaciers Provide Food for Animals That Live in the Ocean
Dr. Fellman, biogeochemist: My favorite science experience is going out to one
of my field sites and finding several chewed salmon carcasses and bear footprints as big as my head!
Dr. Hood, biogeochemist (bī ō jē ō kə mist):
My favorite science experience is being able to climb around
on the glaciers in the Juneau (Alaska) Icefield as part
of my research.
Dr. Spencer, biogeochemist:
My favorite science experience was
witnessing the spring thaw on the Yukon River in Alaska. This is called an “ice-out.” When the
ice melts, it is like a river of ice. You can see it in the photo.
40 The Investi-gator • http://www.scienceinvestigator.org 40 The Investi-gator • http://www.scienceinvestigator.org
Meet the Scientists! continued
Dr. Hernes, aqueous organic geochemist
(aw kwē us ôr gə nik jē ō kə mist): My favorite science experience
is seeing our research published. When a research paper is published,
I know that it will influence how other scientists think
for years to come.
Dr. Edwards, ecologist (ē käl ō jist):
I’ve had so many wonderful experiences as a scientist I can’t pick a favorite. From seeing koalas
(kō ow las) in trees in Australia, to watching a grizzly bear catch salmon in Alaska, my research has allowed me to see
things I never thought I’d see. Aside from the beautiful places, I am happy to know that I have discovered
things that no one knew before. This has given me the feeling that I have
contributed something positive to people.
Dr. Scott, biological systems engineer:
One of my favorite science experiences was standing in the
middle of a Rocky Mountain stream at 2 a.m. watching the
Perseid (pər sē əd) meteor shower. The Perseid meteor shower
occurs every August.
The Investi-gator • http://www.scienceinvestigator.org 41The Investi-gator • http://www.scienceinvestigator.org 41
What is an aqueous
organic geochemist?
This kind of scientist
studies the impacts that
organisms living in water
(or ice) have on Earth.
Thinking About Science
Have you ever wondered how scientists can tell the age of something very old? Often they use the element carbon to help them. Carbon is present in all living and once-living things. There are three types of carbon in living things. They are called carbon 12, carbon 13, and carbon 14. Living things contain very little carbon 14. They contain a lot of carbon 12. The amount of carbon 14 compared to the amount of carbon 12 is the same in all living things.
When living things die, the carbon 14 in them begins to decay. The carbon 12 does not decay. Scientists know exactly how fast carbon 14 decays. They can measure how much carbon 14 is present in something and compare that with how much carbon 12 is present. From this, they can estimate the object’s age up to about 50,000 years old.
What is an
ecologist? This kind
of scientist studies the
relationships of living
things with each other
and with the nonliving
environment.
What is a biogeochemist? This kind of scientist studies the movement of chemical elements, such as carbon and nitrogen. These scientists also study how chemical elements relate to and become a part of living things over time.
What Kind of Scientist?
What is a biological systems engineer? This kind of scientist seeks to design and implement systems. These systems are meant to act like or use life processes for conservation and restoration of the natural environment.
42 The Investi-gator • http://www.scienceinvestigator.org
Thinking About the Environment
Oceans cover most of Earth. They provide a home for many animals and plants. Rivers and bays close to the coast also provide a home for animals and plants. Rivers carry nutrients that were washed into the rivers and bays from the surrounding land. These nutrients become
available to the animals living in the water. This also happens in areas where there are glaciers. As glaciers melt, whatever was frozen in or beneath them runs into coastal rivers and bays (figure 1).
IntroductionFrom studies of rivers with forests along
their banks, scientists know that some plant material gets washed into rivers and bays. Plant material, like all living things, contains carbon. The carbon is used by some animals living in the rivers and bays. These studies
Figure 1. As this glacier melts, its freshwater goes into the bay.
Photo courtesy of Durelle Scott
The Investi-gator • http://www.scienceinvestigator.org 43
have found that as the carbon in the plant material ages, it is less useful to animals living in the water.
In this study, the scientists studied glaciers and their nearby rivers in Alaska (figures 2 and 3). The water coming from glaciers can be quite old. This water might contain nutrients such as carbon. This carbon could be at least 5,000 years old. The scientists wondered about the glacier water running into coastal rivers and bays. They wondered if the carbon in the water was too old to be useful to animals living in the rivers and bays.
State what the scientists wanted to study in the form of a question. Why did the scientists think the carbon might be too old to be useful to animals living in the rivers and bays? (Hint: Reread the last sentence in the first paragraph of the “Introduction.”)
Figure 2. The areas studied by
the scientists.
Figure 3. Glaciers sometimes look like huge rivers of ice.Photo courtesy of
Durelle Scott
Figure 4. Water was collected from rivers
that contained melting glacier water.
MethodThe scientists collected water from 11
areas over 3 days in July 2008 (figure 4). All of the water came from rivers containing melting glacier water. These rivers were not affected by ocean tides. This helped the scientists to be sure that the water was not affected by salt water in the ocean.
The scientists measured the amount of carbon in each container of collected water. They identified whether or not the carbon came from once-living plants or animals that are very old. They used carbon 14 dating to determine the age of the carbon. The pieces of material in the water were so small they could not be seen by the naked eye.
Why did the scientists avoid
getting salt water in their
samples?
Think about the water coming
out of the glaciers. Do you think
the scientists found that the
carbon was quite old? Why or
why not?
44 The Investi-gator • http://www.scienceinvestigator.org
FindingsThe scientists knew that the glaciers
covered ancient forests. The scientists found, however, that glacier water contained little material from ancient forests. They found that most of the glaciers’ carbon came from microbes. Microbes are too small to be seen by the naked eye. They include bacteria, fungi, and algae.
Some kinds of bacteria can live in glaciers. The scientists believe that bacteria living in the glaciers have been eating old plant material for thousands of years. The old plant material came from the ancient forests. The carbon that is coming from glaciers today is made up of the remains of bacteria.
Phot
o co
urte
sy o
f Dur
elle
Sco
tt
The Investi-gator • http://www.scienceinvestigator.org 45
The scientists discovered that the larger the glacier was, the older the carbon was in the glacier water. The scientists also found something different than what scientists before them found. These scientists found that the older the carbon in the glacier water was, the more useful it was to animals living in the rivers and bays. In earlier studies, scientists found the opposite to be true.
DiscussionGlacier water is different than water
flowing down rivers with forests along their banks. It is different in at least two ways. First, the carbon in the glacier water comes from microbes, not from grasses and trees. Second, the older the carbon in the glacier water is, the more useful it is to animals living in the rivers and bays.
As the climate changes, the temperature will rise in the northern regions of Earth (figure 5). This will cause glaciers to melt faster. More carbon will be flowing into rivers and bays near the glaciers. Scientists do not know how this will change the ecosystem of the rivers and bays. They believe, however, that a greater amount of carbon will provide more nutrients to animals living in the rivers and bays.
Are you surprised that the
glacier water contained
little material from ancient
forests? Why or why not?
What might happen to the
flow of glacier water as the
global climate changes?
Figure 5. The northern region of Earth is shown lightly shaded in both images. On the right, you can see the North Pole in the center. The Arctic Circle is an invisible line of latitude on Earth's surface. Within the area north of the Arctic Circle, the sun never rises on the Winter Solstice (December 21) and it never sets on the Summer Solstice (June 21). The northern region of Earth includes an area south of the Arctic Circle, but there is no line that defines the exact area. Glaciers are found in Earth's northern region, including areas south of the Arctic Circle.
In the short term, more carbon and nitrogen might be helpful to animals living in the rivers and bays. In the long term, the scientists wonder what will happen after the glaciers have melted. There may no longer be very old carbon flowing into the rivers and bays.
Are you surprised that carbon
that is thousands of years old
is useful to animals living in
nearby rivers and bays? Why
or why not?
As more glacier water runs
into rivers and bays, will more
or less nutrients be available
to animals living there?
In the long term, what might
happen to the food source
coming from glaciers?
Glossary Algae (al jē): Simple, plantlike organism.
Bacteria (bak tēr ē uh): A large group of one-celled organisms, too small to be seen by the naked eye.
Carbon (kar bun): A chemical element present in all life forms.
Ecosystem (ē kō sis tem): Community of plant and animal species interacting with one another and with the nonliving environment.
Freshwater (fresh wa tur): Having to do with or living in water that is not salty.
Fungi (fun jī): Organisms without chlorophyll that reproduce by spores. Mushrooms, molds, mildews, and toadstools are examples.
Nutrients ( nu trijənt): Any substance found in foods that are necessary for plants and animals.
Accented syllables are in bold.
This article was adapted from Hood, E.; Fellman, J.; Spencer, R.G.M.; Hernes, P.J.; Edwards, R.; D’Amore, D.; Scott, D. 2009. Glaciers as a source of ancient and labile organic matter to the marine environment. Nature. 462: 1044–1047.
46 The Investi-gator • http://www.scienceinvestigator.org
Pronunciation Guideā as in apea as in carē as in mei as in iceō as in gooi as in forAccented syllables are in bold.
ū as in useu as in furü as in tool as in sing as in about (both a and u)
Time required: 30 to 40 minutes
Materials needed: • One page of lined paper and pencil for each student.
• A copy of page 49 for each student. (Optional: An unlined piece of paper, scissors, and glue for each student.)
The question students will answer in this FACTivity is:
What does photographic evidence appear to tell us about glaciers over
the last century?
FACTivity
The process students will use to
answer the question is as follows:
1. Students may work on page 49 in
the journal, or may work from a sheet
that was copied from this page. These
are photographs of five glaciers in
Alaska. The photographs on the left
were taken in the early 1900s. The
photographs on the right were taken in
2000.
2. Students will examine these
photographs and do two main tasks.
• First, students will carefully observe
the photographs and match the
glacier photograph on the left with
the glacier photograph on the right. Students may draw a line connecting the matching glacier photographs. If students are using a copy of the photographic sheet, they may cut the photos out and paste the pairs side-by-side on a separate sheet of paper.• Each student will select two pairs of matching photographs to observe.3. Students will study each pair of photographs for 10 seconds. From this, students should form an overall impression of the photographs and write down their impression on a sheet of paper. In the next 4 minutes, students should compare and contrast the early photographs with the more recent photographs. To assist with the observation, students may divide each photo into quadrants (four equal areas) and study each section to see what new details become visible.4. Based on these observations, students should list three things they might conclude from the two pairs of photographs.
The Investi-gator • http://www.scienceinvestigator.org 47
48 The Investi-gator • http://www.scienceinvestigator.org
5. Hold a class discussion about the
students’ observations. What was the
students’ overall impression? What
did students conclude about glaciers
based on the photographs?
6. Hold a class discussion about
photographic evidence. Some
questions to discuss are:
• Can photographic evidence be
trusted? Why or why not?
• How do photographs provide
information that words cannot?
• What might add to the photographic
evidence presented by these
photographs?
Now, answer the question posed at the
beginning of this FACTivity.
Science as Inquiry: Abilities to do scientific inquiry, Understandings about scientific inquiry
Life Science: Reproduction and heredity, Regulation and behavior, Populations and ecosystems, Diversity and adaptation of organisms
Earth Science: Structure of the Earth system
Science in Personal and Social Perspectives: Natural hazards, Risks and benefits, Science and technology in society
Science and Technology: Understandings about science and technology
History and Nature of Science: Science as a human endeavor, Nature of science
This FACTivity was adapted from http://www.windows2universe.org/teacher_resources/glacier_then_now.pdf. The photographs were provided by the Glacier Photograph Collection. Boulder, Colorado USA: National Snow and Ice Data Center/World Data Center for Glaciology, http://nsidc.org/
FACTivitycontinued
National Science Education Standards addressed in this article:
Web Site Resourceshttp://www.fs.fed.us/r10/tongass/forest_facts/resources/geology/icefields.htm: Tongass National Forest, icefields and glaciers
http://www.pbs.org/wgbh/nova/vinson/glacier.html: The life cycle of a glacier. This slide show traces the journey of a snowflake onto a glacier and eventually reaching the sea.
http://ga.water.usgs.gov/edu/earthglacier.html: U.S. Geological Survey: glaciers and icecaps. Focuses on glaciers as a source of the world’s freshwater.
The research reported in this article was funded in part by the Hydrologic Sciences Program of the U.S. National Science Foundation.
If you are a Project WET-trained educator, you may use the activity “Old Water,” page
171, as a supplemental activity.
The Investi-gator • http://www.scienceinvestigator.org 49
2000. Photo by Bruce F. Molina
2004. Photo by Bruce F. Molina
2004. Photo by Bruce F. Molina
Muir Glacier 1941. Photograph by William O. Field
Toboggan Glacier 1909. Photo by Sidney Page
2004. Photograph courtesy of the U.S. Geological SurveyPedersen Glacier 1909. Photo by Ulysses Sherman Grant
McCarty Glacier 1909. Photograph by Ulysses Sherman Grant
Holgate Glacier 1909. Photograph by Ulysses Sherman Grant
2004. Photograph by Bruce F. Molina